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1194 results:

Person: Niklas Glaser
 
Niklas Glaser is currently working as a Master’s Student on pulse optimizations of superconducting qubit gates. He started his Master thesis in October 2020, within his studies of condensed matter
 
Person: Dr. Daniel Jost
 
Daniel Jost was member of the Gross group at WMI as a Master and Ph.D. Student as well as postdoctoral researcher between 2015 and 2020. Master Thesis: Spin Fluctuations and Superconductivity in
 
Person: Niklas Bruckmoser
 
After focusing on Quantum Information and Technology while studying physics at the Technical University of Munich, Niklas Bruckmoser joined the Quantum Computing group as a Master’s Student in
 
Person: Dr. Daniel Schwienbacher
 
Daniel Schwienbacher was member of the Gross group at WMI as a master and Ph.D. stundent between 2015 and 2021. Master Thesis: Circuit Nano-electromechanics, Transmon Qubits, Nano-strings and
 
Person: Prof. Dr. Matteo Mariantoni
 
Matteo Mariantoni was Member of the Gross group at WMI as a Ph.D. student between 2003 and 2009. Ph.D. Thesis: New Trends in Superconducting Circuit Quantum Electrodynamics: Two Amplifiers, Two
 
News: Contactless high performance power transmission
 
Superconducting coils for contactless power transmission in the kilowatt range
 
News: Open Quantum Researcher/Engineer positions (m/f/d)
 
to join our team working on quantum technologies for scalable superconducting qubit quantum processors.
 
News: Characterization and Tomography of a Hidden Qubit
 
Have you ever wondered how to control and measure a hidden superconducting qubit?
 
Course: Applied Superconductivity 2: from superconducting quantum circuits to microwave quantum optics (0000001704) S 2020
 
Applied Superconductivity 2: from superconducting quantum circuits to microwave quantum optics (0000001704) S 2020
 
Course: Exercise to Applied Superconductivity 2: from superconducting quantum circuits to microwave quantum optics (0000004169) W 2020
 
Exercise to Applied Superconductivity 2: from superconducting quantum circuits to microwave quantum optics (0000004169) W 2020
 
Course: Revision Course to Superconducting Quantum Circuits (0000000963) S 2018
 
Revision Course to Superconducting Quantum Circuits (0000000963) S 2018
 
Course: Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000961) S 2016
 
Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000961) S 2016
 
Course: Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000962) W 2015
 
Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000962) W 2015
 
Course: Superconductivity and Low Temperature Physics 1 (0000000020) S 2013
 
The content of the lecture includes the following topics: Basics properties of superconductors and superconducting materials (different types of superconducting materials, superconductors in a
 
Course: Advances in Solid State Physics (0000000476) S 2012
 
Within the seminar students give talks on current topics in condensed matter physics. The seminar aims to give a closer look at new developments in condensed matter physics and to show how these
 
Course: Superconducting Quantum Circuits (0000001370) W 2006
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Quantum Circuits, and Microwave Quantum Optics (0000001704) S 2007
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Exercise to Applied Superconductivity: Josephson Effects, Superconducting Quantum Circuits, and Microwave Quantum Optics (0000004169) S 2023
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001847) W 2025
 
Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001847) W 2025
 
Course: Exercise to Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001848) S 2026
 
Exercise to Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001848) S 2026
 
Course: Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Superconductivity and Low Temperature Physics 1 (0000000020) S 2026
 
- Basics (superconducting materials, superconductors in a magnetic field, type-I and type-II superconductors, thermodynamic properties) - Phenomenological description of superconductivity (London
 
Course: Quantum Computing with Superconducting Qubits: architecture and algorithms (0000004750) S 2026
 
Quantum Computing with Superconducting Qubits: architecture and algorithms (0000004750) S 2026
 
Course: Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000004752) S 2026
 
Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000004752) S 2026
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Tutorial to Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000004169) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Quantum Computing with Superconducting Qubits: architecture and algorithms (0000001090) S 2026
 
Quantum Computing with Superconducting Qubits: architecture and algorithms (0000001090) S 2026
 
Course: Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000001911) S 2026
 
Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000001911) S 2026
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Tutorial to Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000004169) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Revision Course to Superconducting Quantum Circuits (0000005084) S 2026
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Tutorial to Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000004169) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Tutorial to Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000004169) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
Course: Superconducting Quantum Circuits (0000000622) S 2026
 
For approximately 10 years, superconducting quantum circuits printed on silicon chips are used to study the fundamental laws of quantum mechanics. Two prototypical examples for such circuits are
 
Course: Superconducting Quantum Circuits (0000001370) S 2026
 
see http://www.ph.tum.de/mh?mid=PH1322
 
Course: Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum Circuits (0000001704) S 2026
 
see http://www.ph.tum.de/mh?mid=PH2157
 
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